SEVA 3.0: an Update of the Standard European Vector Architecture for Enabling Portability of Genetic Constructs Among Diverse Bacterial Hosts

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2019 Nov 20

PMID 31740968

Citations 41

Authors

Esteban Martinez-Garcia

Angel Goni-Moreno

Bryan Bartley

James McLaughlin

Lucas Sanchez-Sampedro

Hector Pascual Del Pozo

Clara Prieto Hernandez

Ada Serena Marletta

Davide De Lucrezia

Guzman Sanchez-Fernandez

Sofia Fraile

Victor de Lorenzo

Affiliations

Soon will be listed here.

Abstract

The Standard European Vector Architecture 3.0 database (SEVA-DB 3.0, http://seva.cnb.csic.es) is the update of the platform launched in 2013 both as a web-based resource and as a material repository of formatted genetic tools (mostly plasmids) for analysis, construction and deployment of complex bacterial phenotypes. The period between the first version of SEVA-DB and the present time has witnessed several technical, computational and conceptual advances in genetic/genomic engineering of prokaryotes that have enabled upgrading of the utilities of the updated database. Novelties include not only a more user-friendly web interface and many more plasmid vectors, but also new links of the plasmids to advanced bioinformatic tools. These provide an intuitive visualization of the constructs at stake and a range of virtual manipulations of DNA segments that were not possible before. Finally, the list of canonical SEVA plasmids is available in machine-readable SBOL (Synthetic Biology Open Language) format. This ensures interoperability with other platforms and affords simulations of their behaviour under different in vivo conditions. We argue that the SEVA-DB will remain a useful resource for extending Synthetic Biology approaches towards non-standard bacterial species as well as genetically programming new prokaryotic chassis for a suite of fundamental and biotechnological endeavours.

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